US20080023035A1

Movatterモバイル変換

Info

Publication number: US20080023035A1
Application number: US11/831,564
Authority: US
Inventors: Gun Ho HA; Jin Seo; Chang Yun; Jin Kim; Chang Lee; Yun Park
Original assignee: Individual
Current assignee: LG Electronics Inc
Priority date: 2005-12-10
Filing date: 2007-07-31
Publication date: 2008-01-31
Anticipated expiration: 2026-11-30
Also published as: US7770253B2

Abstract

A vacuum cleaner includes a dust collector that compresses dust stored inside a dust container to minimize the volume of the dust. The dust collector would include one or more pressing plates that are used to compress the dust stored in dust collector. Various methods are used to control movements of the movable pressing plates to facilitate the compression operations. Also, various methods are used to determine when the dust collector is full and needs to be emptied.

Description

This application claims priority to the filing dates of Korean Patent Application No. KR2005-0121279, filed Dec. 20, 2005, Korean Patent Application No. KR2005-0126270, filed Dec. 20, 2005, Korean Patent Application No. KR2005-0134094, filed Dec. 29, 2005, Korean Patent Application No. KR2006-0018119, filed Feb. 24, 2006, Korean Patent Application No. KR2006-0018120, filed Feb. 24, 2006, Korean Patent Application No. KR2006-0040106, filed May 3, 2006, Korean Patent Application No. KR2006-0045415, filed May 20, 2006, Korean Patent Application No. KR2006-0045416, filed May 20, 2006, Korean Patent Application No. KR2006-0046077, filed May 23, 2006, Korean Patent Application No. KR2006-0044359, filed May 17, 2006, Korean Patent Application No. KR2006-0044362, filed May 17, 2006, Korean Patent Application No. KR2006-0085919, filed Sep. 6, 2006, Korean Patent Application No. KR2006-0085921, filed Sep. 6, 2006, and Korean Patent Application No. KR2006-0098191, filed Oct. 10, 2006, the contents of all of which are hereby incorporated by reference. This application is a continuation of U.S. application Ser. No. 11/565,241, filed Nov. 30, 2006. This application is also a continuation-in-part of U.S. application Ser. No. 11/565,206, filed on Nov. 30, 2006. The contents of both prior applications are hereby incorporated by reference.

FIELD

The present invention relates to a removable dust collector of a vacuum cleaner. More particularly, the invention relates to mechanisms for increasing the dust collecting capacity of the dust collector, and methods of operating those mechanisms.

BACKGROUND

Conventional art vacuum cleaners can include a removable dust collector for storing collected dust. These types of removable dust collectors are particularly common on cyclone type vacuum cleaners. Such vacuums are configured such that the user can remove the dust collector, empty it of the collected dust, and then replace the dust collector on the vacuum cleaner.

A typical dust collector according to the related art, as shown inFIG. 1, includes adust container11 formed in a substantially cylindrical shape, alid12 for opening and closing thedust container11, and ahandle13 disposed on the outer surface of thedust container11. In this embodiment, anintake port11afor suctioning outside air is formed on the upper outer surface of thedust container11. Anexhaust port11bfor exhausting air that has undergone the dust separating process is formed at the central portion of thelid12.

The upper portion of thedust container11 forms a cyclone that uses a difference in centrifugal force on the air and the dust (the cyclone principle) to separate the dust from the air. The lower portion of thedust container11 forms a dust bin for storing dust that is separated from the air by the cyclone.

Theintake port11ais oriented in a tangential direction relative to the upper outer surface of thedust container11. This ensures that the incoming air and dust moves in a spiraling direction along the inner wall of thedust container11. Theexhaust port11bis coupled to anexhaust member14 that is cylindrical in shape with a plurality of through-holes formed on the outer surface thereof. The air that is separated from the dust within thedust container11 is exhausted through the through-holes of theexhaust member14 and through theexhaust port11b.

During operation of the vacuum cleaner incorporating this dust collector, the collected dust within the container tends to circulate around the bottom interior of thecontainer11. When operation of the vacuum cleaner stops, the collected dust settles on the floor of thedust container11 and is stored therein at a low density.

Thus, in a dust collector according to the related art, when a predetermined amount of dust has been collected inside the container, during the operation of the dust collector, the dust circulates along the inner walls of the dust bin and rises. When the dust rises, it tends to blocks the cyclone formed in the upper space of the dust bin. This causes the separation effect of the cyclone to deteriorate, and not all the dust in the incoming airstream can be separated. As a result, the unseparated dust is exhausted with the air through the exhaust member and theexhaust port11b.

Also, when the operation of thedust collector10 ends, and the collected dust settles on the bottom of the dust bin, the collected dust has a very low density. In other words, a relatively small amount of dust inside thedust container11 can takes up an excessive volume of thecontainer11. This means that the dust container must be emptied frequently in order to maintain an acceptably low level of dust within the container, which in turn ensures that the vacuum continues to operate in an efficient manner.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiments of the invention and together with the description serve to explain the principle of the invention. In the drawings:

FIG. 1 is a schematic sectional view of a related art dust collector which can be used in a vacuum cleaner;

FIG. 2 is a perspective view of an embodiment with the dust collector separated from a main body of the vacuum cleaner;

FIG. 3 is a perspective view the dust separator portion of the dust collector inFIG. 2;

FIG. 4 is a cutaway perspective view of the dust separator ofFIG. 3;

FIG. 5 is a phantom perspective view of a dust container portion of the dust collector inFIG. 2;

FIG. 6 is a sectional view of the dust container portion ofFIG. 5;

FIG. 7 is a sectional view of the dust container portion inFIG. 5 showing a driving mechanism formed on the floor thereof;

FIG. 8 is a phantom perspective view of the dust container portion ofFIG. 5 with a first compressing plate that has rotated;

FIG. 9 is a sectional view of the dust container portion ofFIG. 8;

FIG. 10 is a bottom plan view showing a driving mechanism formed on the floor of the dust container portion ofFIG. 8;

FIGS. 11aand11bare plan views showing a process of compressing dust in a dust container portion of a dust collector;

FIG. 12 is an exploded perspective view of a dust container portion having a manual-type rotating apparatus for compressing plates;

FIG. 13 is bottom plan view of the driving mechanism provided on the floor of the dust container portion ofFIG. 12;

FIG. 14 is a perspective view of another embodiment where a dust collecting unit is removably mounted on a main body of a vacuum cleaner;

FIG. 15 is a perspective view showing the dust collecting unit inFIG. 14 separated from its receiving portion on the main body;

FIG. 16 is a cutaway perspective view of the dust collecting unit inFIG. 14;

FIG. 17 is an enlarged view of section A inFIG. 16;

FIG. 18 is an exploded perspective view showing how a driving unit for compressing dust in the dust collecting unit is assembled;

FIGS. 19aand19bare plan views showing how a dust collecting unit of a vacuum cleaner compresses dust;

FIG. 20 is a disassembled view of a cyclone and a dust container from the dust collecting unit inFIG. 16;

FIG. 21 is a perspective view of the cyclone inFIG. 20 as seen from underneath;

FIG. 22 is a flowchart of a method for operating a dust compressing collector;

FIG. 23 is a flowchart of one embodiment of step S100 in the method illustrated inFIG. 22;

FIGS. 24ato24eare plan views illustrating dust compressing processes in a dust container of a dust collecting unit;

FIG. 25 illustrates another method of compressing dust in a dust collection unit;

FIG. 26 illustrates another method of compressing dust in a dust collection unit;

FIG. 27 illustrates an alternate embodiment of a vacuum cleaner with a removable dust collection unit;

FIG. 28 illustrates an embodiment of a vacuum cleaner that includes indicator to inform a user when a dust collection unit needs to be emptied;

FIG. 29 is a block diagram of elements of an a vacuum cleaner;

FIG. 30 illustrates another method of compressing dust in a dust collection unit and of providing an indication that a dust collection unit is full;

FIG. 31 illustrates a pulse train emitted by a counter of a vacuum cleaner;

FIG. 32 illustrates another method of operating a vacuum cleaner;

FIGS. 33aand33billustrate the power applied to a suction motor of a vacuum cleaner and the suction achieved as a dust collection unit of the vacuum cleaner becomes more full;

FIG. 34 is a block diagram of elements of an a vacuum cleaner;

FIG. 35 illustrates another method of compressing dust in a dust collection unit of a vacuum cleaner

FIGS. 36aand36billustrate current and power applied to a dust compressing plate motor of a vacuum cleaner as a dust compressing operation is performed;

FIG. 37 illustrates another method of compressing dust in a dust collection unit and of providing an indication that a dust collection unit is full; and

FIG. 38 illustrates a method of stopping a vacuum cleaner when the dust collection unit becomes full.

DETAILED DESCRIPTION

Reference will now be made in detail to preferred embodiments, examples of which are illustrated in the accompanying drawings. Wherever possible, the same reference numbers will be used throughout the drawings to refer to the same or like parts.

Referring toFIG. 2, a basic structural description of a vacuum cleaner according to an embodiment of the present invention will be given. In this embodiment, adust collector200 for separating and collecting dust is removably mounted on amain body100. An air suctioning device (not shown), for generating force to suction air, is disposed within themain body100. The air suctioning device would typically include a fan-motor assembly provided in an air flow passage communicating with thedust collector200.

The fan-motor assembly would generate a suctioning force to suction outside air through a suctioning hole formed on the bottom of a suctioning nozzle. A mainbody intake port110 is provided at the front, lower portion of themain body100 of the vacuum cleaner for communicating with the suctioning nozzle. A mainbody exhaust port120 for exhausting air separated from the dust in the dust collector is disposed on a side of themain body100.

Thedust collector200 of the vacuum cleaner according to the present invention functions to separate and store dust included in air that flows by means of the operation of the air suctioning device. Thedust collector200 includes adust separator210 for separating dust from flowing air, and adust container220 for storing the dust separated by thedust separator210.

In this embodiment, thedust separator210 includes acyclone211 for separating the dust contained in the air using the cyclone principle. The dust that is separated by thecyclone211 is stored inside thedust container220. Of course, in other embodiments, some other type of dust separation mechanism could be used to separate dust from the incoming airstream. A vacuum cleaner using any sort of dust separation mechanism would still fall within the scope of the invention.

Thedust collector200 in this embodiment of the present invention is a separable type dust collector whereby thedust separator210 and thedust container220 can be separated. However, in other embodiments the outer walls of thedust separator210 and thedust container220 may be integrally formed.

Thedust collector200 is removably held in a dustcollector mounting portion130. The dustcollector mounting portion130 may be disposed at the front or elsewhere on themain body100 of the vacuum cleaner.

The dust separator210 (or the cyclone211) is provided on a side of thedust container220. In the present embodiment, thecyclone211 is provided at the top of thedust container220.

Referring toFIGS. 3 and 4, anintake port211afor incoming air containing dust is provided at the top outer surface of thecyclone211. Anexhaust port211bfor exhausting air that has undergone a first dust separating process within thecyclone211 is formed in the center of the ceiling of thecyclone211.

The air and dust that enter the inside of thecyclone211 through theintake port211aare guided in a direction approximately tangential to the inner walls of thecyclone211. To accomplish this, theintake port211ais either provided on the outer surface of thecyclone211 in an approximately tangential direction thereto, or there are guide ribs disposed on the inner walls of theintake port211aor thecyclone211, so that the air and dust flowing through theintake port211ais guided in a direction approximately tangential to the inner walls of thecyclone211.

Also, ahollow exhaust member211cis coupled to theexhaust port211b. A plurality of through-holes are formed in theexhaust member211cfor allowing air that has undergone a dust separating process to be exhausted therethrough.

The roof of thecyclone211 is formed of acover211d, which is removably coupled around the upper perimeter of thecyclone211. Thecyclone211 and thedust container220 may be partitioned from each other by a dividingplate230. Thus, in this embodiment, with thecyclone211 installed in the upper portion of thedust container220, the dividingplate230 simultaneously forms the ceiling of thedust container220 and the floor of thecyclone211.

The dividingplate230 has adust entrance231 formed at an edge portion thereof so that dust separated in thecyclone211 can enter adust chamber222 of thedust container220. Thedust entrance231 is formed from an edge of the dividingplate230 towards the center thereof. In some embodiments, there may be only onedust entrance231. In other embodiments, there may be a plurality of dust entrance holes.

During operation of the vacuum cleaner, dust would spiral along the inner walls within thecyclone211. Gravity would cause the dust to fall into thedust container220 through thedust entrance231. Also, the dividingplate230 prevents dust within thedust container220 from rising and entering thecyclone211.

In this embodiment, both thedust container220 and thecyclone211 can be removed from themain body100 of the vacuum cleaner. Also, in this configuration thedust container220 is detachably provided below thecyclone211. The dividingplate230 is integrally formed at the bottom of thecyclone211. Mote specifically, the dividingplate230 is integrally connected around the lower circumference of thecyclone211, with the exception of the portion forming thedust entrance231.

Anupper handle212 and alower handle221 are respectively provided on the outer surface of thecyclone211 and the outer surface of thedust container220. Therefore, a user may separate only thedust container220 from the main body to empty it. On the other hand, when cleaning of the cyclone's211 interior is required, the user may separate thecyclone211 from themain body100 of the vacuum cleaner and open thecover211dto easily clean the inside of thecyclone211.

Although not shown, a fixing apparatus for fixing thecyclone211 and thedust container220 to themain body100 of the vacuum cleaner may be provided.

In other embodiments, the cyclone may be more permanently mounted on the main body of the vacuum cleaner, and only the dust container would be removable. In still other embodiments, the cyclone and dust container may be integrally formed in a single body which is removably mounted on the main body.

A structure for maximizing the amount of dust that can be stored in a dust container will now be described with reference toFIGS. 5-7.

FIG. 5 is a phantom perspective view of a dust container of the dust collector inFIG. 2,FIG. 6 is a sectional view of the dust container inFIG. 5, andFIG. 7 is a sectional view of the dust collector inFIG. 5 showing a driving mechanism formed on the floor thereof.

Referring toFIGS. 5 through 7, thedust collector200 has a pair of compressing

plates

310 and320 which can operate to compress dust stored in the container to reduce the volume of the dust. Reducing the volume in this fashion increases the total amount of dust that can be stored in the container before it needs to be emptied.

In this embodiment, at least one of the pair of compressing

plates

310 and320 is configured to move within thedust container220, thereby compressing dust between the two compressing

plates

310 and320. The moving compressing plates may be rotatably installed within thedust container220. In other words, one or both of the pair of compressing

plates

310 and320 may move to narrow the gap between the two compressing

plates

310 and320. This gathers dust between the pair of compressing

plates

310 and320 and compresses the dust into a highly dense state.

For purposes of the following description, one of the pair of compressing

plates

310 and320 will hereinafter be referred to as thefirst compressing plate310, and the other will be referred to as thesecond compressing plate320.

When both thefirst compressing plate310 and thesecond compressing plate320 are rotatably installed within thedust container220, both the first and

second compressing plates

310 and320 are designed to rotate towards one another, so that the gap between one side of thefirst compressing plate310 and the side of thesecond compressing plate320 facing thefirst compressing plate310 is reduced. This results in dust disposed between the first and

second compressing plates

310 and320 being compressed.

However, in this embodiment, only thefirst compressing plate310 is rotatably provided inside thedust container220. The second compressing plate is fixed.

Thefirst compressing plate310 rotates within thedust chamber222 by means of a manual-type rotating mechanism. The free edge of thefirst compressing plate310 follows a curve as the plate rotates. The inner wall of thedust chamber222 encloses an imaginary curve formed by the free edge of thefirst compressing plate310. Here, thedust chamber222 forms a substantially cylindrical inner space.

Because thesecond compressing plate320 is fixed at a predetermined position within thedust chamber221, as thefirst compressing plate310 rotates, the mutual interaction of thesecond compressing plate320 and thefirst compressing plate310 causes a volume of the dust stored inside thedust container220 to be reduced. In other words, thefirst compressing plate310 rotates by means of the manual-type rotating mechanism to push dust towards one of the two sides of thesecond compressing plate320, thereby compressing the dust inside thedust container220.

Here, thesecond compressing plate320 may be provided in an approximate radial disposition between the inner surface of thedust chamber222 and a rotating axis (the central point of rotation) of thefirst compressing plate310. Mote specifically, thesecond compressing plate320 has one end thereof integrally connected to the inner surface of thedust chamber222 and the other end extending towards the center of thedust chamber222. Therefore, thesecond compressing plate320 entirely or partially seals a passage between the inner surface of thedust chamber222 and the central axis of thedust chamber222 such that the dust pushed by thefirst compressing plate310 is compressed together with thesecond compressing plate320.

In this embodiment, the floor of thedust container220 forms one end of the seal for thedust chamber222, and the cyclone is provided above thedust chamber222. However, in other embodiments, the dust container could have different configurations. For instance, in another embodiment, thedust container220 could be installed in a prone position on themain body100 of the vacuum cleaner.

However, for the sake of descriptive convenience, the below description will be given based on thedust container220 being installed in an upright position on themain body100 of the vacuum cleaner. Therefore, one end of thedust chamber222 becomes the bottom or floor of thedust chamber222. Also, the top of thedust chamber222 is opened, and its interior is formed in a cylindrical shape. Of course, the dust chamber could have any number of other shapes.

The bottom end of thesecond compressing plate320 may either be integrally formed with the floor of thedust chamber222 or located proximally thereto. The upper end of thesecond compressing plate320 may be proximally disposed to the upper end of thedust chamber222. More specifically, the upper end of thesecond compressing plate320 may be formed to be proximal to the bottom surface of the dividingplate230. This helps to minimize leakage of the dust that is pushed by thefirst compressing plate310 through gaps formed at the edges of thesecond compressing plate320.

The above-configured first and

second compressing plates

310 and320 may be formed as rectangular plates. However, depending on the interior shape of thedust chamber222, the first and second compressing plates could have a variety of other shapes as well. Also, although this embodiment shows the first and second compressing plates with approximately the same overall shape, in other embodiments, the first and second compressing plates could have different shapes.

The manual-type rotating mechanism includes anoperating part410, and adriving mechanism420 for transferring driving force from the operatingpart410 to the movablefirst compressing plate310. The operatingpart410 is a structure for a user to operate in order to exert force to compress the dust stored in thedust container220. In this embodiment, the operatingpart410 is a structure that includes alever411. In more detail, thelever411 is disposed on the dust container handle (or the lower handle) provided on the outer surface of the dust container, in order to increase operating convenience of thelever411.

Below, for the sake of descriptive convenience, thelower handle221 be referred to as the dust container handle. Thelever411 is movably disposed within thehandle221. When a user pulls thelever411, thefirst compressing plate310 may be configured to rotate within thedust chamber222 and compress the dust together with thesecond compressing plate320.

One end of the lever411 (in this embodiment, the upper end) is pivotably connected to thedust container handle221. The opposite end of thelever411 is connected to thedriving mechanism420. Accordingly, when a user pulls the lever towards the inner surface of the dust container handle221 (that is, in a direction outward from the dust container220), the pulling force of the user is transferred by thedriving mechanism420 to thefirst compressing plate310, thereby causing thefirst compressing plate310 to rotate.

Thedriving mechanism420 includes a

gear mechanism

421 and422 for transferring the force exerted on thelever411 to thefirst compressing plate310 through engaged gears.

Of course, thedriving mechanism420 may not be a gear mechanism, but may alternately include components from a belt or chain-driven mechanism, or from a friction wheel system. However, a gear-type mechanism is an effective choice for transferring the driving force.

In this embodiment, the

gear mechanism

421 and422 changes linear movement into rotational movement, imparting rotational force to arotating axis311 at the rotational center of thefirst compressing plate310. In the present embodiment, the

gear mechanism

421 and422 consists of a rack bar and a pinion gear. Therack bar421 moves linearly by means of the operatingpart410, or more specifically, thelever411. Therack bar421 includes arack421awith teeth that engage with teeth of thepinion gear422, so that thepinion gear422 is rotated by being engaged with therack421a.

In the present embodiment, thepinion gear422 is directly coupled to therotating axis311 of thefirst compressing plate310. In other words, the rotatingaxis311 of the first compressing plate is inserted and fixed in the central portion of thepinion gear422. Therotating axis312 of thefirst compressing plate310 shares the same axis with the axis line forming the center of thedust chamber222.

The free outer end of thefirst compressing plate310 may rotate while being disposed as close as possible to the inner surface of thedust chamber222. Thesecond compressing plate320 seals a space between therotating axis311 of the first compressing plate and thedust chamber222.

Although not shown, at least one gear may be further provided between therack bar421 and thepinion gear422.

In the above structure, the gear mechanism is disposed on the floor of thedust container220. Thus, adriving mechanism compartment440, in which the

gear mechanism

421 and422 is installed, is formed at the lower end of thedust chamber222.

Although not shown, thedriving mechanism compartment440 may include afloor cover441 detachably coupled to the floor of thedust container220, for opening and closing the bottom end of thedriving mechanism compartment440, in order to install the gear mechanism.

FIG. 7 is a view showing thedust container220 from the bottom with thefloor cover441 removed. Thepinion gear422 is coupled to the lower end of therotating axis311 of the first compressing plate, and therack bar421 is installed to be engaged to thepinion gear422. The lower end of therotating axis311 of the first compressing plate passes through the floor of thedust chamber222 and protrudes downward from the ceiling of thedriving mechanism compartment440.

Also, aguide rib442 for guiding therack bar421 in a linear movement may be disposed on thedriving mechanism440. Here, theguide rib442 may be integrally formed with the ceiling of thedrive mechanism compartment440 to protrude downward therefrom, and therack bar421 is disposed between thepinion gear422 and theguide rib442.

Thefirst compressing plate310 may be configured so that it returns to its original position when an external force exerted on thelever411 is removed. The original position of thefirst compressing plate310 is a position in which thefirst compressing plate310 contacts a surface of thesecond compressing plate320, or a position proximal to one side surface of thesecond compressing plate320. For this, the dust collector may include a returning unit connected to the manual-type rotating mechanism, for restoring thefirst compressing plate310 to its original position.

In the present embodiment, the returning unit includes areturn spring430. Thereturn spring430 may be a compression spring installed between the lever and thehandle221. One end of thereturn spring430 may be connected to the outer surface of thelever411, and the other end may be connected to the inner surface of the dust container handle221 facing the outer surface of thelever411.

Therefore, when a user pulls thelever411 outwards, thereturn spring430 is compressed. When the pressure on thelever411 is removed, the compressedreturn spring430 expands to simultaneously return therack bar421 and thefirst compressing plate310 to their original positions.

Thedriving mechanism420 and theoperating part410 may be directly connected, or thedriving mechanism420 may be connected to theoperating part410 via ashock absorbing spring423. In the embodiment shown inFIG. 7, therack bar421 is connected to thelever411 through ashock absorbing spring423. One end of theshock absorbing spring423 is connected to therack bar421, and the other end is connected to the lower end of thelever411.

Theshock absorbing spring423 prevents excessive force from being transferred to thefirst compressing plate310. That is, as thefirst compressing plate310 rotates to compress dust, when it reaches a point where it can no longer rotate, and force is continuously exerted on thelever411, theshock absorbing spring423 absorbs the external force, and prevents excessive force from being transferred to thefirst compressing plate310 and/or thesecond compressing plate320.

Also, in the process of manually manipulating thelever411 as described above to compress dust, the dividingplate230 prevents the dust being compressed between the pair of compressing

plates

310 and320 from rising up from the dividingplate230.

A method of operating the above-described dust collector will now be described with reference toFIGS. 8-10.FIG. 8 is a phantom perspective view of a dust container with a first compressing plate that has rotated some amount.FIG. 9 is a sectional view of the dust container inFIG. 8, andFIG. 10 is a bottom plan view showing a driving mechanism formed on the floor of the dust container inFIG. 8.

Referring toFIGS. 8 through 10, when a user first wishes to compress collected dust, the user pulls thelever411 to rotate thefirst compressing plate310 towards the other side of thesecond compressing plate320. Dust that was spread out on the floor of the dust chamber222 (as shown inFIG. 6) is swept towards the other side of thesecond compressing plate320FIG. 10 shows the movement of the gear mechanism (that is, therack bar421 and the pinion gear422) as seen from below thedust container220.

After the dust is compressed by the above manual operation, the user releases thelever411, whereupon thereturn spring430 returns thefirst compressing plate310 to its original position, as shown inFIGS. 5 through 7.

Operations of a vacuum cleaner having the above-described configuration will now be described.

First, when power is supplied to the vacuum cleaner, the outside air that is suctioned through the suctioning nozzle passes though the mainbody intake port110 and enters theintake port211aof the cyclone. The air that enters through the cyclone'sintake port211ais guided in a tangential direction to the inner wall of thecyclone211 to form a spiraling current. As a result, dust contained in the air is separated therefrom by means of centrifugal force, and the dust particles descend under the force of gravity.

The dust will moves in a circular or spiral flow along the inner walls of thecyclone211 and ultimately passes though adust entrance231 of the dividingplate230. The dust particles are then stored in thedust chamber221.

The air that is separated from the dust by thecyclone211 is first exhausted through anexhaust member211cand theexhaust port211b, and then passes the fan-motor assembly and is exhausted from themain body100 of the vacuum cleaner via the mainbody exhaust port120.

Referring toFIGS. 11aand11b, the dust inside thedust chamber221 is compressed between the first and

second compressing plates

310 and320 by means of the manually-operatedlever411, so that the volume of the dust is minimized and the storage capacity of dust in thedust chamber221 increases. Since the operation of thefirst compressing plate310 interacting with thesecond compressing plate320 has already been described above, a repetition thereof will not be made.

Thedust container220 that stores the compressed dust may be detached from themain body100 of the vacuum cleaner and emptied at appropriate times. In other words, when a user separates thedust container220 from themain body100 of the vacuum cleaner and flips the dust container upside-down, the compressed dust inside can be emptied to the outside.

A second embodiment of a manually operated mechanism for compressing dust in a dust collector will now be described with reference to FIGS.12 and13.FIG. 12 is an exploded perspective view of a dust container and a manually operated rotating apparatus according to this second embodiment, andFIG. 13 is bottom plan view of the driving mechanism shown inFIG. 12.

In this embodiment, the manual-type rotating device has an operating part such as thelever411 provided on the dust container handle as in the first embodiment. The force imparted on thelever411 is transferred to thefirst compressing plate310 through adriving mechanism450. Because the coupling configuration of the lever is the same as in the description provided above, a repetitive description thereof will not be given.

Thedriving mechanism450 includes a

gear mechanism

451 and452. In this embodiment, the

gear mechanism

451 and452 is composed of arack bar451, which is moved by means of the operating part (that is, the lever411). Apinion gear452ais rotated by therack bar451. A drivengear452bis engaged with and driven by thepinion gear452a. Here, as described in the first embodiment, therack bar451 includes a rack engaged with thepinion gear452a. The drivengear452bis directly connected to therotating axis311 of the first compressing plate.

In the above-described configuration, the

gear mechanism

451 and452 is provided on the floor of thedust container220. Thedust chamber222 includes adriving mechanism compartment440, for housing the driving mechanism formed on the bottom thereof. Thedriving mechanism compartment440 may have afloor cover441 that is detachably coupled to the floor of thedust container220, to enable the installation of the gear mechanism, and for sealing the bottom of thedust container220.

FIG. 13 shows thedust container220 viewed from the bottom thereof with thefloor cover441 removed. The drivengear452bis coupled to therotating axis311 of the first compressing plate, and the rack of therack bar451 is engaged with thepinion gear452a.

In this embodiment, in order to install therotating axis311 of the first compressing plate, ahollow fixing shaft312 disposed vertically along the central axis of thedust chamber222 is fixed to the floor of thedust chamber222. Therotating axis311 of the first compressing plate includes an inner shaft and an outer shaft.

Here, theinner shaft311apasses from the lower end of thedust container220 through the floor of thedust chamber222, and is inserted in the hollow cavity of the fixingshaft312. Also, the bottom of theinner shaft311ais installed in the central ceiling portion of thedriving mechanism compartment440, and is coupled to the drivengear452b.

Additionally, a cavity is formed within theouter shaft311b, so that theouter shaft311bcan be fitted over theinner shaft312. The upper portion of theinner shaft311ais coupled to theouter shaft311b, and the outer and

inner shafts

311band311arotate simultaneously.

To enable the outer and

inner shafts

311band311ato rotate simultaneously, the upper portion of theinner shaft311aforms amulti-edged protrusion311c, and a multi-edge receptacle (not shown) for receiving themulti-edged protrusion311cinserted and coupled therein is formed in the upper end of the cavity of the outer shaft. Also, the outer surface of theouter shaft311bis integrally formed with thefirst compressing plate310.

Next, thepinion gear452ais connected to apinion shaft452cprotruding upward from the ceiling of thedriving mechanism compartment440, and is engaged with the drivengear452b. Also, astopper screw452d, for preventing the disengagement of thepinion gear452afrom thepinion shaft452c, is screwed to thepinion shaft452 to support the bottom of thepinion gear452a.

Guide ribs

442 and443 for guiding a linear movement of therack bar451 may be disposed in thedriving mechanism compartment440.

In the present embodiment, therack bar451 has a body that is in a rough Y-shape. Here, the Y-shaped body may have a pair ofbranches451athat are parallel. One of thebranches451aof the Y-shaped body forms the rack on its inner surface.

To more reliably guide the linear movement of therack bar451, thedriving mechanism compartment440 may have pair offirst guide ribs442 integrally formed on the ceiling and protruding in a downward direction. The pair offirst guide ribs442 run parallel to each other, and the pair ofbranches451aof the Y-shaped body are disposed between the pair offirst guide ribs442 to slide therebetween. A pair ofsecond guide ribs443 may be integrally formed with the ceiling of thedriving mechanism compartment440 to run parallel to one another, so that thebranches451bof the Y-shaped body may slide therebetween. Therefore, therack bar451 has a secure passage for movement formed by the first and

second guide ribs

442 and443.

In order to increase rotating torque of the manual-type rotating device, the diameter of the drivengear452bmay be smaller than the diameter of thepinion gear452a.

Thefirst compressing plate310, as described in the first embodiment, may be configured to return to its original position when the external force imparted on thelever411 is removed. In this embodiment, a return unit that is connected to the manual-type rotating device may be further provided, to return thefirst compressing plate310 to its original position. The return unit includes areturn spring460. Thereturn spring460 is an extension spring installed between the inner wall of thedriving mechanism compartment440 and therack bar451.

One end of thereturn spring460 is connected to a first connectingpart461aprovided on the inner wall of thedriving mechanism compartment440, and the other end of thereturn spring460 is connected to a second connectingpart461bprovided on the Y-shaped body of thelever411 of therack bar451. Thereturn spring460 crosses the lower end of thepinion gear452a, and is connected to thetack bar451. When a user pulls thelever411 outward, thereturn spring460 is extended, When the external force on thelever411 is removed, the extendedreturn spring460 contracts and returns therack bar451 and thefirst compressing plate310 to their original positions.

Thedriving mechanism450 and thelever411 of the operating part may be directly connected. However, in this embodiment, thedriving mechanism450 is indirectly connected to theoperating part410 via a shock absorbing spring. Therack bat451 is connected to thelever411 through theshock absorbing spring453. Theshock absorbing spring453 has one end connected to therack bar451 and the other end connected to the lower end of thelever411.

Theshock absorbing spring453 prevents excessive force being transferred to thefirst compressing plate310. That is, when thefirst compressing plate310 reaches a point where it can no longer proceed while rotating to compress dust, and force is continuously exerted on thelever411, the shock absorbing spring absorbs the external force, preventing the transfer of excessive force to the first and/orsecond compressing plates310 and/or320.

In the above-described embodiments, the dust collector with the compressing plates has been used in a canister-type vacuum cleaner. However, the present invention is not limited thereto, and may be applied to an upright-type, a robot-type, or other types of vacuum cleaners.

A vacuum cleaner using the above-described dust compressing plates has many advantages over related art vacuum cleaners. First, a dust collector as described above minimizes the volume of dust stored inside the dust container when a user manually compresses the dust. As a result, the dust container's dust storing capacity is maximized.

Second, the dust collector according to the present invention has compressing plates that compress dust through a rotational movement within the dust container to reduce the volume of the dust. This helps to prevent a scattering of collected dust upward into the cyclone, thereby improving the dust collecting capability of the dust collector.

Third, because the movable compressing plate automatically resumes its original position the compressed dust within the dust container can easily be emptied to the outside.

Another embodiment having an automatic motorized mechanism for compressing dust in the dust collection unit will now be described with reference toFIGS. 14-21. The vacuum cleaner in this embodiment, as shown inFIG. 14, includes amain body100, and adust collector200. A mainbody intake port110 is provided at the front, lower portion of themain body100 of the vacuum cleaner, for communicating with a suctioning nozzle, and a mainbody exhaust port120 for exhausting air separated from the dust in thedust collector200 is disposed on a side of themain body100.

As in the previous embodiment, the dust collecting unit includes adust separator210 for separating dust from flowing air, and adust container220 for storing the dust separated by thedust separator210. Thedust separator210 includes acyclone211 which uses the cyclone principle. The dust that is separated by thecyclone211 is stored inside thedust container220.

Details of the dust collector will now be described with reference toFIGS. 15-18.FIG. 15 is a perspective view showing the dust collecting unit inFIG. 14 separated from its receiving portion on the main body.FIG. 16 is a cutaway perspective view of the dust collecting unit inFIG. 14.FIG. 17 is an enlarged view of section A inFIG. 16.FIG. 18 is an exploded perspective view showing how a driving unit for compressing dust in the dust collecting unit is assembled.

As shown inFIGS. 16-18, a pair of compressing

plates

310 and320 are provided in the dust collecting unit. The dust compressing plates act to reduce the volume of the dust stored in thedust container220, thereby increasing the overall dust storage capacity of the dust collection unit.

Here, the pair of compressing

plates

310 and320 mutually interact to compress dust and reduce its volume, so that amount of dust stored per unit of volume (or the density) in thedust container220 can be increased. In this embodiment, at least one of the pair of compressing

plates

310 and320 is movably provided within thedust container220, and dust is compressed between the pair of compressing

plates

310 and320.

In embodiments where both the first and

second compressing plates

310 and320 are movably disposed within thedust container220, the first and

second compressing plates

310 and320 both rotate toward one another, so that the space between one side of thefirst compressing plate310 and the one side of thesecond compressing plate320 facing the one side of thefirst compressing plate310 becomes narrower. Thus dust that is disposed between the first and

second compressing plates

310 and320 is compressed.

However, in this embodiment, only thefirst compressing plate310 is movably disposed within thedust container220. The inner surface of thedust chamber221 is opened to allow rotation of thefirst compressing plate310. The inner surface of thedust chamber221 forms a curve that is traced by the free edge of thefirst compressing plate310 as it rotates within thedust chamber221.

In the present embodiment, thesecond compressing plate320 is fixed within thedust chamber221. Thesecond compressing plate320 may be provided between the inner surface of thedust chamber221 and the rotating center of thefirst compressing plate310, which is defined by an axis of arotating shaft342. Thesecond compressing plate320 forms a wall that defines a plane between an axis of therotating shaft342 and the inner surface of thedust chamber221. Thesecond compressing plate320 may entirely or partially seal a passage defined between the inner surface of thedust chamber221 and the axis of therotating shaft342. When dust is pushed by thefirst compressing plate310, thesecond compressing plate320 can compress the dust together with thefirst compressing plate310.

In some embodiments, oneend321 of thesecond compressing plate320 may be integrally formed on the inner surface of thedust chamber221, and the other end may be integrally formed with a fixingshaft322 coaxially provided with therotating shaft342 of thefirst compressing plate310. Of course, the one end of thesecond compressing plate320 may be integrally formed with the inner surface of thedust chamber221, or the other end only may be integrally formed with the fixingshaft322. In other words, thesecond compressing plate320 is fixed to at least one of the inner surface of thedust chamber221 and the fixingshaft322.

Even if the one end of thesecond compressing plate320 is not integrally connected to the inner surface of thedust chamber221, the end of thesecond compressing plate320 may be disposed proximally to the inner surface of thedust chamber221. Also, even if the other end of thesecond compressing plate320 is not integrally fixed to the fixingshaft322, the other end of thesecond compressing plate320 may be proximally disposed to the fixingshaft322. Also, thesecond compressing plate320 may be either integrally connected with an end of thedust chamber221 or is disposed proximately to an end of thedust chamber221.

When the second compressing plate is configured as described above, dust that is pushed by thefirst compressing plate310 is prevented from leaking through gaps formed at sides of thesecond compressing plate320.

The first and

second compressing plates

310 and320 may be formed in rectangular shapes. However, depending on the interior shape of thedust chamber221, the dust compressing plates may have other shapes.

Therotating shaft342 of thefirst compressing plate310 may be disposed on the same axis as the center of thedust chamber221. Also, thedust chamber221 may have a cylindrical interior space.

Here, the free edge of the first compressing plate310 (that is, the outer edge) may be disposed as close as possible to the inner surface of thedust chamber221 while it rotates.

The fixingmember322 may protrude inward from one end of thedust chamber221. In order to assemble therotating shaft342, the fixingshaft322 may have a hollow cavity formed along the length of its interior, and a through-hole (not shown) may be formed at one end of thedust chamber221 to communicate with the interior of the fixingshaft322.

A vacuum cleaner according to this embodiment would also include adriving unit500 connected to therotating shaft342 of thefirst compressing plate310, for rotating thefirst compressing plate310. Referring toFIGS. 17 and 18, the drivingunit500 includes a

driving mechanism

510 and520 for transferring a driving force for rotating thefirst compressing plate310 to the rotating shaft.

The

driving mechanism

510 and520 includes a drivengear510 which cam be coupled to therotating shaft342 of thefirst compressing plate310. Adriving gear520 transfers a driving force to the drivengear510. Thedriving gear520 is coupled to a rotating shaft of a drivingmotor530 and is turned by the drivingmotor530. Accordingly, the driving motor can be used to cause thefirst compressing plate310 to rotate automatically to compress dust stored inside thedust container220.

In this embodiment, one end portion of thedust container220 forms the floor of thedust container220 while it forms a side portion of thedust chamber221 at the same time. Thefloor222 of thedust container220 is supported by the floor of the dust collectingunit mounting portion130 on themain body100.

The drivingmotor530 is disposed below the dust collectingunit mounting portion130. Thedriving gear520 is coupled with the rotating shaft of the drivingmotor530 and is disposed on the floor of the dust collectingunit mounting portion130. A portion of the outer surface of thedriving gear520 is exposed in the floor of the dust collectingunit mounting portion130.

The lower side of the floor of the dust collectingunit mounting portion130 may form a motor compartment (not shown) so that the drivingmotor430 can be installed therein. The approximate center of the dust collectingunit mounting portion130 forms an opening for exposing a portion of the outer circumference of thedriving gear520.

When therotating shaft342 of thefirst compressing plate310 is rotatably installed to pass through the floor of thedust chamber221, and the cavity of the fixingshaft322, the drivengear510 is coupled to the lower end of therotating shaft342. To allow the rotating shaft342 (to which thefirst compressing plate310 is coupled) to be assembled to thedust container220, therotating shaft342 includes anupper shaft342acoupled to thefirst compressing plate310 and alower shaft342bcoupled to the drivengear510. A stepped portion, supported by the upper end of the fixingshaft322, is formed on theupper shaft342a, and the lower end of theupper shaft342ais coupled to the upper portion of thelower shaft342b. Theupper shaft342ais inserted a predetermined depth from the upper end of the fixingshaft322 into the cavity. Thelower shaft342bpasses through a through-hole (not shown) formed in the floor of thedust container220 or one end of thedust chamber221, and is inserted in the cavity of the fixingshaft322.

The upper portion of thelower shaft342bis coupled to the lower end of theupper shaft342a, and rotates integrally with theupper shaft342aand thelower shaft342b. To allow theupper shaft342aand thelower shaft342bto integrally rotate, a coupling protrusion may be formed on an end of one of theupper shaft342aand thelower shaft342b, and a coupling receptacle may be formed on the other shaft. For instance, the lower surface of theupper shaft342amay have a coupling protrusion formed in the shape of a “−” or a “+” sign, and the upper surface of thelower shaft342bmay also be formed in a “−” or a “+” sign.

The lower portion of thelower shaft342bis integrally coupled with the drivengear510, and is installed below the floor of thedust container220. When the dust collection unit is mounted on the main body, the portion of the outer surface of the driving gear that is exposed in the floor of the dust collectingunit mounting portion130 is engaged with the drivengear510 provided below the floor of thedust container220.

The drivingmotor430 may be a motor capable of both forward and reverse operation. In other words, the drivingmotor430 may be a motor capable of rotating in either direction. This would give thefirst compressing plate310 the capability of both forward and reverse rotation. In this instance, dust could pushed against both sides of the second (fixed) pressingplate320, by rotating thefirst compressing plate310 in both directions, as shown inFIGS. 19aand19b.

Also, even when thefirst compressing plate310 reaches a point where it cannot move any further in the compressing directions after operating for a predetermined duration to compress the dust, the force from the driving motor that is relayed to therotating shaft312 may be continuously applied for another predetermined duration.

Also, the drivingmotor430 may rotate thefirst compressing plate310 at an equal angle and speed in both directions for a predetermined period of operation, in order to more easily compress stored dust.

The drivingmotor430 may be a synchronous motor. Since a synchronous motor is well known to those skilled in the art, a description thereof will not be provided. It is worth stating, however, that a synchronous motor may be applied to the present invention from a technical perspective.

Referring toFIGS. 20 and 21, thedust separator210, or thecyclone211, may be disposed above thedust container220. Anintake port211amay be disposed tangentially to the upper, outer surface of thecyclone211, for admitting an incoming flow of dust laden air. Anexhaust port211bmay be formed at the center of the cyclone's211 ceiling for exhausting air that has been filtered in the first filtering stage within thecyclone211.

Ahollow exhaust member211cmay be coupled to theexhaust port211b. The outer surface of theexhaust member211chas a plurality of through-holes formed therein to exhaust air that has undergone a dust separating process of thecyclone211. The ceiling of thecyclone211 includes acover211dthat is removably attached around the upper perimeter of thecyclone211.

Thecyclone211 and thedust container220 are separated by a dividingplate230. The dividingplate230 forms the ceiling of thedust chamber221. Here, the upper portions of the first and

second compressing plates

310 and320 may be disposed close to the bottom of the dividingplate230.

Adust intake231 is disposed on an edge of the dividingplate230, so that the dust separated by thecyclone211 can enter thedust chamber221. Thedust intake231 is formed at an out edge of the dividingplate230.

In some embodiments, thedust intake231 may be located at a side of thedust chamber221 that is opposite to the location of the fixed second compressingplate320. This arrangement allows for the quantity of the dust compressed on either side of thesecond compressing plate320 to be maximized. In addition, if the dust in thedust chamber221 is swept by the movable first compressing plate away from thedust intake231, the dust will be less likely to scatter back up to thecyclone211 when the vacuum cleaner is being operated.

In this embodiment, thedust container220 is separated from thecyclone211 in themain body100 of the vacuum cleaner. Thedust container220 is removably provided at the lower portion of thecyclone211. Also, the dividingplate230 is integrally formed with thecyclone211, forming the floor of thecyclone211.

With the exception of a portion of the edge of the dividingplate230 that forms thedust intake231, the dividing plate is integrally connected to the lower perimeter of thecyclone211. This prevents dust from rising into the cyclone during the compressing process, and also prevents dust from scattering from thedust container220 due to the flow of air inside thecyclone211.

In some embodiments, a user may separate only thedust container220 to empty it. On the other hand, when cleaning of the cyclone's211 interior is required, the user may separate thecyclone211 from themain body100 of the vacuum cleaner and open thecover211dto easily clean the inside of thecyclone211.

To remove and attach thedust container220 and thecyclone211 as above, anupper handle212 and alower handle223 are respectively formed on the outer surfaces of thecyclone211 and thedust container220.

Also, in order to couple thedust container220 and thecyclone211, the dust collector has a hook fastener. The outer, lower surface of thecyclone211 has ahook receptacle241 formed thereon. The upper, outer surface of thedust container220 has ahook242 formed thereon, so that thehook242 may selectively be coupled to thehook receptacle241, in order to fix thedust container220 beneath thecyclone211.

In embodiments where thefirst compressing plate310 is a rotating plate and thesecond compressing plate320 is a fixed plate, thefirst compressing plate310 should be positioned apart from the compressed dust when the vacuum cleaner is turned off so that dust can be easily emptied from the dust chamber.

Also, when a quantity of dust exceeding a predetermined amount is collected inside thedust chamber221, a signal may be given to a user that it is time to empty thedust container220. This would help to prevent a drop in vacuuming ability and an overloaded driving motor. For this purpose, an alarm indicator (not shown) may be installed on themain body100 of the vacuum cleaner or on the dust collecting unit, so that when the range of movement of thefirst compressing plate310 falls below a predetermined range, due to a large quantity of dust having been collected in thedust chamber221, the alarm indicator may notify the user that it is time to empty thedust container220.

In some embodiments the vacuum cleaner may include both a main cyclone and a secondary cyclone. For instance, the above-describedcyclone211 could be called the main cyclone, and thedust chamber221 could be called the main chamber. In some embodiments, the vacuum cleaner may further include a secondary cyclone unit that is mounted on the main body. Also, anauxiliary dust chamber224 may be provided on the dust collecting unit to store dust separated in the secondary cyclone unit.

In the embodiment shown inFIG. 20, anauxiliary dust chamber224 is provided on the outer surface of the dust collecting unit with its upper end open. Anauxiliary dust entrance213 on the outer surface of themain cyclone211 communicates with theauxiliary dust chamber224. The outer wall of theauxiliary dust entrance213 has an auxiliarydust entrance hole213athat may be formed to selectively communicate with a dust exhaust of the secondary cyclone. The floor of theauxiliary dust entrance213 may be opened and connected to the top end of theauxiliary dust chamber224 so that dust separated in the secondary cyclone can fall into and be stored in theauxiliary dust chamber224.

In embodiments with motor driven compressing plates, no action on the part of the user is required to compress the dust in the dust collection unit. Also, if movements of the compressing plates are used to determine when the dust collection unit is full, the vacuum cleaner can provide the user with an indication that it is time to empty the dust collection unit.

A method for operating a dust compressing collector will now be described with reference toFIGS. 22 and 23. This method could be performed by a vacuum cleaner with a motorized set of compression plates, as in the embodiment described immediately above. This method could also be performed in an embodiment where two or more compression plates move towards one another to compress dust.

With reference toFIG. 22, during a first step S100 of the method, the dust compressing collector compresses dust stored in a dust container by the interaction of a pair of compressing plates to reduce the volume of the dust. This compressing step could involve one compressing plate moving in a single direction to compress dust against one side of a fixed compressing plate. Alternatively, one movable compressing plate could move in two opposite directions to compress dust against opposite sides of a fixed compressing plate. In still other embodiments, two or more movable compressing plates could be moved towards each other to compress dust between the plates.

In a second step S200, a rotation range θ of a first compressing plate is detected. In other words, a detector would monitor the movement of at least one compressing plate during the compressing operation step S100, and the detector would determine the rotation angle traversed by the compressing plate during the compressing operation.

The method would then proceed to step S310 where the detected rotation angle traversed by the compressing plate would be compared to a predetermined rotation angle θp. If the angle traversed by the compression plate was greater than the predetermined angle θp, the method would loop back to step S100. If the angle traversed by the compression plate was less than or equal to the predetermined angle θp, the method would proceed on to a warning step S320.

In step S320, the vacuum cleaner would provide an indication to the user that the dust collection unit was full and needed to be emptied. The warning step S320 could include sounding an audible warning tone, illuminating a warning light, or by various other methods.

FIG. 23 illustrates details of the operations that may be performed in one embodiment of the compression step S100 of the method shown inFIG. 22. In step S110, a first compressing plate would be moved in a first direction to compress dust against one side of a fixed compressing plate. When the first compressing plate has stopped moving, in step S130, the first compressing plate would apply continuous pressure against the dust for a first predetermined period of time.

Next, in step S120, the first pressing plate would be rotated in the opposite direction to compress dust against the other side of the second, fixed compression plate. In step S140, once the first compressing plate has stopped moving in the second direction, the first compressing plate would apply continuous pressure against the dust for a second predetermined period of time.

Here, the firstpressure applying plate310 repeatedly rotates in forward and reverse directions with a predetermined angular velocity.

The dust compressing method illustrated inFIG. 23 will now be further described with reference toFIGS. 24ato24e.

More specifically, as illustrated inFIG. 24a, the firstpressing plate310 would rotate in a first direction towards one side of the second (fixed) pressingplate320. Therefore, the volume of dust in themain chamber221 of the dust collection unit would be reduced. When the firstpressing plate310 cannot move any further towards the secondpressing plate320, the firstpressing plate310 would continuously compress dust against the first side of the secondpressing plate320 for a predetermined period of time, for instance, 3-5 seconds.

Next, as illustrated inFIG. 11B, the firstpressing plate310 would be rotated in the opposite direction towards the second side of the secondpressing plate320. Therefore, the volume of dust would be further reduced. When the firstpressing plate310 cannot move any further, the firstpressing plate310 would continuously compresses dust against the secondpressing plate320 for a second predetermined period of time, for instance 3-5 sec.

The above processes would be repeated during a vacuum cleaner operation, as illustrated inFIGS. 24ato24d. As the operations continue, the rotational range of the firstpressing plate310 would be continuously or periodically input to a controller of the vacuum cleaner. By tracking the amount of rotation of the first pressing plate, the controller would be able to determine an amount of dust that has been collected in thedust container220. The smaller the rotation of the first pressing plate, the greater the amount of collected dust.

As illustrated inFIG. 24e, when the rotation range of the firstpressure applying plate310 is less than a predetermined angle, the controller would notify the user that the dust collection unit needs to be emptied.

FIG. 25 is a flow chart showing another method of compressing foreign substances within the dust collector. This method senses the pressure being applied by the first movable compressing plate during the compression operation.

First, in step S410, a firstpressing plate310 is rotated in a first direction to compress dust against a first side of a fixed second pressing plate. In step S420, the resistance force generated during the pressing process is sensed. If the resistance force is less than a predetermined value, the method loops back to step S41, and rotation of the first pressing plate continues. These steps are repeated until the resisting sensing step determines that the value of the resistance force generated during the pressing process is equal to or greater than the predetermined value. At that point, the method proceeds to stepS430, where rotation of the firstpressing plate310 is stopped. In other words, the power being applied to thedrive motor430 is cut off, and thus the firstpressing plate310 is stopped, while still compressing the dust between the pressing plates.

In step S430, the method waits for a predetermined period of time to elapse, and then the method proceeds to step S440, the first pressing plate is rotated in the opposite direction to compress dust against the second side of the second pressing plate. The method then proceeds to step S450 where the resistance force being generated by the pressing operation is again checked. If the resistance force is less than a predetermined value, the method loops back to step S440, and the first pressing plate is allowed to continue rotating in the second direction. Steps S440 and S450 are repeated until the checking step S450 indicates that the resistance force being generated by the pressing operation is equal to or greater than a predetermined value. When this determination is made, the method proceeds to step S460, where further rotation of the first pressing plate is halted. The method waits for a predetermined period of time, and then proceeds to step S500.

In step S500, the vacuum cleaner determines if the pressing operation should be continued. If so, the method returns to step S410. If not, the method ends.

Typically, the above-described methods would be continued until an angle to which the firstpressing plate310 is rotated becomes smaller than a predetermined angle. If that occurs, the vacuum cleaner would determine that the dust collection unit is full and needs to be emptied. Alternatively, the process would end when the vacuum cleaner is shut off.

FIG. 26 is a flow chart showing a method of controlling the pressing plates when the operation of the cleaner is to be stopped. As noted above, when the vacuum cleaner is operating, the pressing plates would be in continuous operation, compressing the dust being collected in the dust collection unit. This could mean rotating a first pressing plate in a single direction to compress dust against a single side of a fixed pressing plate. It could also mean moving a pressing plate in two opposing directions to compress dust against two opposite sides of a fixed pressing plate. It could also mean moving multiple pressing plates with respect to each other to compress dust between the two moving pressing plates. Regardless, then the user decides to turn the vacuum cleaner off, the pressing plates will be at some random point in the pressing cycle.

The method illustrated inFIG. 26 begins with the vacuum cleaner in operation, and a normal pressing operating occurring in step S600. In step S610 a check is performed to determine if the user has decided to stop the suction motor. If not, then the process return to step S600. If the checking step S610 determines that the user has elected to shut off the vacuum cleaner, then the method proceeds to step S620.

In step S620, a first pressing plate is moved towards another pressing plate to accomplish a compressing operation. The method then moves on to step S630 where is check is performed to determine if the pressing force has met or exceeded a predetermined value. If not, the method returns to step S620, where the pressing operation is continued. If the checking step S630 determines that the pressing force has met or exceeded a predetermined value, then the method proceeds to step S640, where further movement of the pressing plate is halted. The method then ends.

In the above-described method, the operations of the pressing plates are not stopped right after the operation of the suction motor is stopped. Instead, at least one movable pressing plate continues to move and only stops after the moving pressing plate compresses any dust against another pressing plate with a certain amount of force. Because the firstpressing plate310 is stopped only after it has moved to a location where it keeps pressing the dust, the compression of the dust is maintained even though the vacuum cleaner is not operated. This, in turn, facilitates the process of emptying thedust collector200 after stopping the vacuum cleaner.

Also, because the pair of

pressing plates

310 and320 continue to press the dust even when the operation of the vacuum cleaner is stopped, compression during the subsequent operation of the vacuum cleaner is facilitated.

In the above method, dust is compressed by the pair of

pressing plates

310 and320 during operation of the vacuum cleaner, and the compression of the foreign substances is maintained after operation of the vacuum cleaner is stopped. In an alternate embodiment, the pair of

pressing plates

310 and320 may perform the compression when the vacuum cleaner is stopped, without performing compression when the vacuum cleaner is in operation. That is, the vacuum cleaner may be configured such that none of the pressing plates move when the cleaner is in operation. Then, when the vacuum cleaner is to be stopped, a compressing operation could be performed as described above.

An alternate embodiment of a vacuum cleaner will now be described with reference toFIG. 27. In this embodiment, a microswitch M is mounted on the main body of the vacuum cleaner adjacent thegear420 driven by themotor870. A terminal extending from a side of the microswitch M bears against the teeth of thegear420. When the motor rotates thegear420, the teeth of thegear420 push the terminal into the microswitch. Thus, as thegear420 rotates, the microswitch is turned on and off.

The on-off signal of the microswitch M is applied to a counter which outputs a high level pulse signal when the microswitch M is turned on and a low level pulse signal when the microswitch M is turned off. Therefore, by measuring the number of pulses (i.e., a switch on-off period), the degree of the rotation of thedriving gear420 can be measured.

The output of the counter can also be used to determine when to stop driving the compressing plate. Specifically, a controller can monitor the output of the pulses generated by the counter. When the motor is driving the compressing plate, and the compressing plate is rotating, the counter will periodically output pulses. However, when the compressing plate can no longer rotate, because the compressing plate has compressed the dirt in the dust collection unit as much as possible, the counter will stop outputting pulses. Then, as in the methods described above, the motor can reverse direction so that the compressing plate is driven in an opposite direction.

As also explained above, in some methods, after apressing plate310 has reached a point where it cannot rotate further, it is preferable that thepressing plate310 remains stationary, thereby compressing any trapped dust, for a predetermined period of time. Thus, when the rotation of apressing plate310 in a first direction stops, the power applied to thecompression motor870 is cut off for a predetermined period of time so that thepressing plate310 remains stationary. After the predetermined time period has elapsed, power is applied to thecompression motor870 so that the firstpressing plate310 can rotate in an opposite direction.

As also mentioned above, when a predetermined amount of dust has been collected in the dust collection unit, it is desirable to provide an indication to the user instructing the user to empty the dust collection unit. This indication can take the form of an illuminated indicator light on the vacuum cleaner.

FIG. 28 shows an embodiment where anindicator872 is provided on thehandle40. Also, in this embodiment, anindicator874 is provided on themain body100. When the predetermined amount or more of dust is collected in the dust collection unit, and thus the rotational range of a pressing plate is restricted to a predetermined amount, or less, one or both of the

indicators

872 and874 can be activated. A particular embodiment may have only anindicator872 on the handle, or only anindicator874 on the main body, or have indicators at both locations.

The

indicators

872 and874 may be LEDs for visually letting the user know that it is time to empty the dust collection unit. Alternatively, the indicators may be speakers aurally letting the user know when it is time to empty the dust collection unit. In still other embodiments, the indicators could take other forms, such as display screens or other devices.

In some embodiments, both a speaker and an LED may be provided. For instance, in the embodiment shown inFIG. 28, theindicator872 on the handle many be a LED, and theindicator874 on the main body may be a speaker. In this instance, both indicators may be activated at the same time. Also, the speaker may be activated for only a predetermined period of time, and then only the LED might remain activated until the user empties the dust collection unit. In still other embodiments, the speaker may generate a tone for a short period of time, but the tone might be periodically repeated until the user empties the dust collection unit.

FIG. 29 a block diagram illustrating elements of an embodiment of a vacuum cleaner. The vacuum cleaner of this embodiment includes acontrol unit810 formed of a microcomputer, an operationsignal input unit820 for selecting a suction power (e.g., high, middle, low power modes), and adust discharge indicator830. The vacuum cleaner also includes asuction motor driver840 for operating thesuction motor850 that is a driving motor for sucking air into the vacuum cleaner. Acompression motor driver860 is used to operate thecompression motor870 which drives compressing plates to compress dust collected in the dust collection unit. Finally, this embodiment includes acounter unit880 for detecting a degree of the rotation of thecompression motor870.

When the user selects one of the high, middle and low modes representing the suction power using the operationsignal input unit820, thecontrol unit810 controls thesuction motor driver840 so that thesuction motor850 can be operated with the suction power corresponding to the selected power mode. That is, thesuction motor driver840 operates thesuction motor850 with the suction power according to a signal transmitted from thecontrol unit810.

As explained above, thecontrol unit810 also operates thecompression motor870 simultaneously with and/or right after the operation of the suction motor is halted. If the compression plates are to be driven while the suction motor is being operated, dust collected in the dust collection unit would be compressed by one or more compressing plates which are rotated by thecompression motor870.

As also explained above, thecounter unit880 would measure movements of the compressing plate by sensing rotations of one of the gears coupled to the compression motor and the movable compressing plate(s). Thecounter unit880 would send a signal to thecontrol unit810 indicative of these movements.

As an amount of dust being compressed in the dust collection unit increases, the reciprocal rotation the compression motor would become reduced. In other words, as more and more dust is stored in the dust collection unit, the movable compressing plate(s) will be able to move through smaller and smaller amounts of rotation before they must stop and reverse direction. When the amount of dust reaches a predetermined level and thus the reciprocal motion of the movable compressing plate(s) is less than a predetermined rotational amount, thecontrol unit810 activates theindicator830 to signal the user that it is time to empty the dust collection unit.

FIG. 30 is a flowchart illustrating a method of operating a vacuum cleaner as illustrated inFIG. 29.FIG. 31 illustrates a waveform of a pulse signal which could be output by acounter unit880 as shown inFIG. 29. A method of operating a vacuum cleaner will now be explained with reference toFIGS. 29-31.

In step S710, a check is performed to determine if the suction motor is being operated. If not, the method loops back to the beginning of the method. A user would begin operating the vacuum cleaner by selecting one of the high, middle and low modes of the operationsignal input unit820. Thecontrol unit810 would then control thesuction motor driver840 so that thesuction motor850 operates with the suction power corresponding to the selected power mode. When thesuction motor850 is operating, the result of the checking step S710 would be positive, and the method would proceed to step S712.

In step S712, thecontrol unit810 would drive thecompression motor870 to compress dust stored in the dust collection unit. This would cause at least one pressing plate to rotate in step S714. Then, in step S716, a check would be performed to determine if the counter is generating pulse output on a regular basis. If so, that would indicate that the compressing plate is still able to move, and the method would loop back to step S714. If the result of the checking step S716 indicates that pulses are no longer being generated by the counter, that would indicate that the compressing plate can no longer move any further to compress dust. In that event, the method would proceed to step S718.

In step S718, the controller would turn off the compression motor. In step S720, three seconds would be allowed to elapse with the compression motor turned off. Although three seconds is used in this embodiment, different delay periods could be used in step S720. In still other embodiments, the delay step S720 might be completely skipped so that no delay occurs.

In step S722, a check is performed to determine if the dust collection unit is full. This can be done in a number of ways. Primarily, this is determined by checking to see if the compressing plate is incapable of moving more than a predetermined angular amount in either direction.

FIG. 31 illustrates a pulse train that will be output by the counter as the compressing plate(s) are moved back and forth to compress dust in the dust collecting unit. When the dust collection unit is empty, the compressing plate moves a considerable distance in each direction. Then, as the dust collection unit becomes full, the compressing plate(s) can move through smaller and smaller angular amounts. Thus, the number of pulses output by the counter gradually decrease.

When the number of pulses that are output by the counter between the time the compressing plate begins moving in a particular direction and the time that is stop is less than or equal to a predetermined number, the controller will determine, in step S722, that the dust collection unit is full. At that point, the method would move on to step S724.

In an alternate embodiment, the pulses could simply be used to determine when the compressing plate stops moving. In other words, when the pulses are no longer being output by the counter, then the compressing plate has stopped moving. In this alternate embodiment, the controller would track the amount of time that elapses between the point in time that the compressing plate begins moving in a certain direction, and the point in time when the compressing plate stops moving. Then, the controller could compare the elapsed time to a predetermined period of time. If the elapsed moving time is less than or equal to the predetermined period of time, the controller would determined, in step S722, that the dust collection unit is full, and the method would move on to step S724.

In some embodiments, the check performed in step S722 would be followed by another check, in step S724, where the controller would determine if the number of pulses, or the elapsed movement time is equal to or less than the predetermined number for three consecutive times that the compressing plate is moved. If not, the method would return to step S710. If so, the method would move on to step S726. In other embodiments, the check performed in step S724 might be skipped.

When the method moves on to step S726, the controller would turn off the suction motor. The method would then proceed to step S728, where the indicator would be activated to inform the user that the dust collection unit is full and needs to be empties.

In alternate embodiments, step S726 might be skipped. This would allow the vacuum cleaner to continue to operate, however, the indicator would still be activated.

FIG. 33ashows how a vacuum cleaner would operate when a substantially constant power is applied to the suction motor as the dust collection unit becomes full. As can be noted inFIG. 33a, as the dust collection unit gets more full, the suction power of the vacuum cleaner deteriorates.

FIG. 33bshow how a vacuum cleaner would operate when the suction power of the vacuum cleaner is kept substantially the same as the dust collection unit becomes full. As can be noted inFIG. 33b, it is necessary to increase the power applied to the suction motor, as the dust collection unit becomes full, in order to ensure that the same amount of suction force is generated.

FIG. 32 illustrates another method for controlling a vacuum cleaner so that it behaves as illustrated inFIG. 33b. In this method, a driving force of a suction motor is varied based on an amount of dust collected in the dust collection unit so that the suction force remains substantially constant.

Referring toFIG. 32, in step S910, the user would begin to operate the vacuum cleaner. During initial operations, in step S920, when the dust collection unit is substantially empty, a relatively low power applied to the suction motor will ensure a certain amount of suction force is generated by the vacuum cleaner.

In step S930, the controller would measure the amount of dust collected in the dust collection unit. This could be done, as described above, by checking the amount of angular movements being made by the dust compressing plates. In step S940, the amount of collected dust would be compared to a predetermined reference amount. If the amount of collected dust is less than the predetermined reference amount, the method would loop back to step S930. If the result of the checking step indicates that the amount of collected dust exceeds the predetermined amount, the method would proceed to step S950, where the amount of power applied to the suction motor would be increased, based on the amount of collected dust, so that the suction force remains substantially the same as when the dust collection unit was empty.

Another method of controlling the pressing plates of a vacuum cleaner will now be described with reference toFIGS. 34-36.FIG. 34 is a block diagram showing elements of a vacuum cleaner.FIG. 35 is a flow chart illustrating steps of a method of controlling a dust compression process.FIG. 36aillustrates the current applied to a motor used to move a compression plate of the vacuum cleaner.FIG. 36billustrates a waveform of power supplied to the compressing plate drive motor

Referring toFIG. 34, the vacuum cleaner includes acurrent detector1010 which detects the amount of current applied to adrive motor1030 that drives a pressing plate. Amotor driver1020 drives thedrive motor1030 based on signals from acontroller1000. Thecontroller1000 also receives a signal from thecurrent detector1010 indicative of the current being applied to thedrive motor1030.

As explained above, during a dust compressing operation, one or more pressing plates are driven back and forth in opposite rotational directions to compress dust. Thedrive motor1030 switches its rotation direction when a value of a resistance force applied by apressing plate310 becomes equal to or greater than a set value.

In this method, the way that the resistance force is determined is by checking the current being applied to the drive motor. As shown inFIG. 36a, when the value of the resistance force applied by thepressing plate310 becomes equal to or greater than a predetermined value, the current of thedrive motor430 momentarily increases. This momentary increase can be detected by the current detector.

In the method illustrated inFIG. 35, in step S1110, the pressing plate is first rotated in one direction. In step S1120, a check is performed to determine if the force applied by the pressing plate has exceeded a predetermined about. If not, the process returns to step S1110, and the pressing plate continues to rotate. If the result of the checking step indicates that the predetermined force has been exceeded, then the method proceeds to step S1130, where the pressing plate drive motor is stopped. The resistance value check is made by checking the current applied to the drive motor. When the current value spikes, thecontroller1000 knows that the resistance value has exceeded the predetermined amount, and thecontroller1000 sends signals to themotor driver1020 to cut off power to thedrive motor1030.

In step S1130, a predetermined period of time is allowed to elapse while the pressing plate remains stationary. Then, in step S1140, the drive motor is operated again to move the pressing plate in the opposite direction.

In step S1150, a check is again performed to determine if the predetermined resistance force has been exceeded as the pressing plate is moving in the opposite direction. Here again, this check is performed by monitoring the current applied to the motor. When the predetermined resistance force has been exceeded, the method proceeds to step S1160 where another predetermined period of time is allowed to elapse while the pressing plate remains stationary.

These steps would be repetitively performed until either the user turns the vacuum cleaner off, or the controller determines that the duct collection unit is full and needs to be emptied.

FIG. 37 illustrates another method of determining when it is necessary to empty the duct collection unit. The method starts in step S1200 where the compression process would be initiated. In step S1210, the controller would note the time period S between point in time when the compression plate begins moving in a particular direction, and the point in time that it stops moving in that direction. Then, in step S1220, the time period S would be compared to a predetermined value. If the time period S is greater than the predetermined time period, the method loops back to step S1210 and the compressing steps continue.

If the time period S is less than the predetermined time period, the controller determines that the dust collection unit may be full. The method would then continue to step S1230 where a check is performed to see if the time period S has been judged to be less than the predetermined period of time for a predetermined number of checks. If not, the method loops back to step S1210. If the time period S has been smaller than the predetermined time period for a predetermined number of checks, the controller determines that the dust collection unit is full, and the method proceeds to steps S1240 where the indicator is activated to inform the user that the dust collection unit needs to be emptied.

In some embodiments, the check performed in step S1230 might be skipped. Thus, the first time that the time period S is less than the predetermined time period, the method would proceed to step S1240 and the indicator would be activated.

However, the check performed in step S1230 may be helpful in preventing a false determination that the dust collection unit is full. For instance, the compressing plate might be halted after less than a full sweep in one direction by factors other than a full dust collection unit. A dust particle might be trapped between the dust container and the compressing plate to prevent normal movement of the compressing plate. In this case, the moving time (S) of the firstpressing plate310 may be artificially reduced. To prevent a false full indication, the checking step S1230 ensures that the movement time period S must be smaller than the predetermined time period for multiple successive sweeps of the compressing plate.

FIG. 38 illustrates a method that a vacuum cleaner would perform when the dust collection unit is full and needs to be emptied. First, in step S1310, the pressing plate would be moved to a position that facilitates emptying of the dust collection unit. The pressing plate could be rotated to a location that is about 180° apart from a stationarypressing plate320. That is, the pressing plate is moved to the maximum distance from the stationarypressing plate320 In other embodiments, the pressing plate may be stopped after it has moved for half of the most recently noted travel time period S discussed above. In this case, the pressing plate would be positioned approximately equidistant from the opposite ends of the collected and compressed dust.

Next, in step S1320, the indicator would be activated. In the case of an indicator light, the lights may be repetitively turned ON and OFF so that user can easily recognize the signal. If the indicator includes a speaker, the speaker may output a buzzing sound or a melody.

Next, in step S1330, a suction motor of the vacuum cleaner would be operated at a predetermined load level for a first set period of time. After the suction motor is operated for the first set period of time at the first load level, in step S1340, the operational load of the suction motor is decreased to a different lower predetermined value. The suction motor is operated at the decreased load level for a second set period of time, and is then shut off Operation of the suction motor at the two different load levels, before shutting it off, is a signal to the user that the vacuum cleaner is being shut down because the dust collector is full. If this was not done, the user might incorrectly conclude that the vacuum cleaner was simply broken. When the operation of the suction motor is stopped, in step S1350, the operation of the indicator(s) is also stopped.

U.S. Pat. Nos. 6,974,488, 6,859,975, 6,782,584, 6,766,558, 6,732,406, 6,601,265, 6,553,612, 6,502,277, 6,391,095, 6,168,641, and 6,090,174 all disclose various types of vacuum cleaners. The methods and devices described above would all be applicable and useful in the vacuum cleaners described in these patents. The disclosure of all of the above-listed patents is hereby incorporated by reference.

Any reference in this specification to “one embodiment,” “an embodiment,” “example embodiment,” etc., means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment of the invention. The appearances of such phrases in various places in the specification are not necessarily all referring to the same embodiment. Further, when a particular feature, structure, or characteristic is described in connection with any embodiment, it is submitted that it is within the purview of one skilled in the art to effect such feature, structure, or characteristic in connection with other ones of the embodiments.

Although embodiments have been described with reference to a number of illustrative embodiments thereof, it should be understood that numerous other modifications and embodiments can be devised by those skilled in the art that will fall within the spirit and scope of the principles of this disclosure. More particularly, various variations and modifications are possible in the component parts and/or arrangements of the subject combination arrangement within the scope of the disclosure, the drawings and the appended claims. In addition to variations and modifications in the component parts and/or arrangements, alternative uses will also be apparent to those skilled in the art.

Claims

1. A method of operating a vacuum cleaner, comprising:

operating a suction motor of the vacuum cleaner at a first power level;

determining an amount of dust and foreign objects stored in a dust collection unit of the vacuum cleaner;

comparing the determined amount of dust and foreign objects to a predetermined amount; and

increasing the power level of the suction motor to a second power level which is higher than the first power level if the result of the comparison step indicates that the determined amount of dust and foreign objects exceeds the predetermined amount.

2. The method ofclaim 1, wherein the determining step comprises:

moving a compressing plate in the dust collection unit to compress dust and foreign objects stored in the dust collection unit;

determining how far the compressing plate is able to move within the dust collection unit; and

determining an amount of dust and foreign objects stored in the dust collection unit based on the determined amount of movement of the compressing plate.

3. The method ofclaim 2, wherein the moving step comprises moving the compressing plate in a reciprocating fashion.

4. The method ofclaim 2, wherein the moving step comprises rotating the compressing plate back and forth in clockwise and counterclockwise directions within the dust collection unit to compress dust and foreign objects in the dust collection unit.

5. The method ofclaim 4, wherein the step of determining how far the compressing plate is able to move comprises determining how fat the compressing plate is able to rotate.

6. The method ofclaim 4, wherein the step of determining how far the compressing plate is able to move comprises determining how long it takes for the compressing plate to fully rotate in either the clockwise or counterclockwise direction before the compressing plate stops.

7. The method ofclaim 4, wherein the step of determining how far the compressing plate is able to move comprises determining how long it takes for the compressing plate to rotate in either the clockwise or counterclockwise directions from a reference position to a position at which the compressing plate stops.

8. The method ofclaim 1, wherein the comparing step comprises comparing the determined amount of dust and foreign objects to first and second predetermined amounts.

9. The method ofclaim 8, wherein the increasing step comprises:

increasing the power level of the suction motor to a second power level which is higher than the first power level if the result of the comparison step indicates that the determined amount of dust and foreign objects exceeds the first predetermined amount and is less than the second predetermined amount; and

increasing the power level of the suction motor to a third power level which is higher than the first and second power levels if the result of the comparison step indicates that the determined amount of dust and foreign objects exceeds both the first and second predetermined amounts.

10. A vacuum cleaner, comprising:

a suction unit that operates to suck air into the vacuum cleaner;

a dust separation unit that separates dust and foreign objects from air sucked into the vacuum cleaner;

a dust collection unit which collects dust separated in the dust separation unit; and

a controller that varies the power of the suction unit depending on the amount of dust and foreign objects stored in the dust collection unit.

11. The vacuum cleaner ofclaim 10, further comprising a sensor coupled to the controller that detects the amount of dust and foreign objects stored in the dust collection unit.

12. The vacuum cleaner ofclaim 10, wherein the controller operates such that the suction of the vacuum cleaner remains substantially constant regardless of the amount of dust and foreign objects stored in the dust collection unit.

13. The vacuum cleaner ofclaim 10, wherein the controller can cause the suction unit to operate at a plurality of different power levels depending on the amount of dust and foreign objects stored in the dust collection unit.

14. The vacuum cleaner ofclaim 10, further comprising a movable dust compression plate that compresses dust in the dust collection unit.

15. The vacuum cleaner ofclaim 14, wherein the controller monitors the amount that the dust compression plate is able to move, and wherein the controller uses the amount of movement to determine how much dust and foreign objects are stored in the dust collection unit.

16. The vacuum cleaner ofclaim 14, wherein the dust compression plate moves in a reciprocal fashion to compress dust and foreign objects in the dust collection unit.

17. The vacuum cleaner ofclaim 16, wherein the dust compression plate rotates back and forth in clockwise and counterclockwise directions within the dust collection unit.

18. The vacuum cleaner ofclaim 17, wherein the controller monitors the rotational movements of the dust compression plate to determine the amount of dust and foreign objects stored in the dust collection unit.

19. The vacuum cleaner ofclaim 18, wherein the controller monitors the amount of time that it takes for the compression plate to move in a certain rotational direction to determine the amount of dust and foreign objects stored in the dust collection unit.

20. The vacuum cleaner ofclaim 18, further comprising a detector coupled to the controller that detects the angular rotational movements of the compression plate.